Evolution of rheologically heterogeneous salt structures: a case study from  the NE Netherlands

Raith, Alexander F.; Strozyk, Frank; Visser, J.; Urai, János L.

doi:10.5194/se-7-67-2016

Cited by 22 publications

(43 citation statements)

References 44 publications

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“…A 3-D depth-migrated seismic profile from the Groningen High of the Netherlands (Raith et al, 2016) illustrates some of the resulting geometries. It crosses two pillows: the Slochteren Pillow is in the common footwall to west-dipping and southdipping presalt extensional faults, and the Veendam Pillow is located partly over the southern flank of an E-W trending graben and partly over the graben itself (Fig.…”

Section: Southern Permian Basinmentioning

confidence: 99%

“…2d). Modern seismic data, especially 3-D depth-migrated data (e.g., Gamboa et al, 2008;Van Gent et al, 2011;Fiduk and Rowan, 2012;Cartwright et al, 2012;Strozyk et al, 2012Strozyk et al, , 2014Gvirtzman et al, 2013;Jackson et al, 2014Jackson et al, , 2015Raith et al, 2016;, can reveal the full three-5 dimensional geometry but lack the resolution to image the small-scale structure, especially in mobile lithologies ( Fig. 2e).…”

Section: Introductionmentioning

confidence: 99%

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Deformation of intrasalt competent layers in different modes of salt tectonics

Rowan

Urai

Fiduk³

et al. 2019

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Abstract. Layered evaporite sequences (LES) comprise interbedded weak layers (halite and, commonly, bittern salts) and strong layers (anhydrite and usually non-evaporite rocks such as carbonates and siliciclastics). This results in a strong rheological stratification, with a range of effective viscosity up to a factor of 105. We focus here on the deformation of competent intrasalt beds in different modes of salt tectonics using a combination of conceptual, numerical and analog models, and seismic data. In bedding-paralell extension, boudinage of the strong layers forms ruptured stringers, within a halite matrix, that become increasingly isolated with increasing strain. In bedding-parallel shortening, competent layers tend to maintain coherency while forming harmonic, disharmonic, and polyharmonic folds, with the rheological stratification leading to buckling and fold growth by bedding-parallel shear. In differential loading, extension and the resultant stringers dominate beneath suprasalt depocenters while folded competent beds characterize salt pillows. Finally, in tall passive diapirs, stringers generated by intrasalt extension are rotated to near vertical in tectonic melanges during upward flow of salt. In all cases, strong layers are progressively removed from areas of salt thinning and increasingly disrupted and folded in areas of salt growth as deformation intensifies. The varying styles of intrasalt deformation impact seismic imaging of LES and associated interpretations. Ruptured stringers are often visible where they have low dips, as in slightly extended salt layers or beneath depocenters, but are usually not imaged in tall passive diapirs due to steep dips. In contrast, areas of slightly to moderately shortened salt typically have well imaged, mostly continuous intrasalt reflectors, although seismic coherency decreases as deformation intensifies. Similarly, wells are most likely to penetrate strong layers in contractional structures and salt pillows, less likely in extended salt because they might drill between stringers, and unlikely in tall passive diapirs because the stringers are near-vertical. Thus, both seismic and well data may be interpreted to suggest that diapirs and other areas of more intense intrasalt deformation are more halite rich than is actually the case.

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Section: Southern Permian Basinmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Deformation of intrasalt competent layers in different modes of salt tectonics

Rowan

Urai

Fiduk³

et al. 2019

Preprint

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“…However, when salt or evaporites are composed of “stringers” of carbonate, anhydrite, or clay, they provide good reflectors within the salt and opportunities to investigate internal salt structures and deformation (Geluk, ; C. A.‐L. Jackson et al, ; C. A. Jackson et al, ; M. Jackson et al, ; Peters et al, ; Raith et al, ; Schléder et al, ; Strozyk et al, , ; Talbot & Jackson, ; Van Gent et al, ).…”

Section: Introductionmentioning

confidence: 99%

Multiphase Structural Evolution and Geodynamic Implications of Messinian Salt‐Related Structures, Levant Basin, Offshore Israel

et al. 2018

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Speculations surround salt deformation in the Mediterranean Basins, both related to the deformation history and the triggers for halokinesis since the onset of the Messinian Salinity Crisis. This work presents a detailed description of the mechanisms driving internal and external deformation of a salt giant from the Levant Basin, offshore Israel. The intrasalt siliciclastic layers generate good internal reflectivity within the Messinian evaporites, allowing a thorough elucidation of the complex evolution and nature of syn-Messinian and post-Messinian structures. We have identified three distinct phases of deformation in the deep basin, based on the orientation, timing, and geometry of their related structures: The first phase is characterized by small-scaled, gravity-driven, contractional faults and folds oriented N-S that have been overprinted by a second syn-Messinian, NW-SE trending, deformation phase affecting the clastic bundles. This latter deformation phase is the cause of truncation of the intrasalt stringers on the intra-Messinian truncation surface. The third deformation phase occurred in the Pleistocene and affected all strata from the Messinian salt to the seabed. This deformational phase produced thrust, strike-slip, and normal faults, but the dominant orientation of the thrust faults and folds is NNW-SSE. Our study demonstrates that the first deformation phase was caused by regional uplift along the Levant margin during the Messinian, the second is a response to basin subsidence toward the Cyprus Arc, also syn-Messinian, and the third phase is likely related to the reorganization of the African-Eurasian plate boundary and activity along the Dead Sea Transform after the Messinian Salinity Crisis.Plain Language Summary A thick body of alternating evaporites and claystones was deposited in the Mediterranean Sea during the infamous Messinian Salinity Crisis, between 5.93 and 5.33 million years ago. This event is in itself poorly understood, as both the cause(s) and the consequence(s) of this crisis is heavily disputed. In this study, we use traditional seismic interpretation as well as geometrical observations and seismic attribute analysis to understand the tectonic movements and how they have generated different fault types in the subsurface of offshore Israel during and after the deposition of the evaporite package. We present three different deformation phases and discuss their possible trigger mechanisms. The good quality of the seismic data used in the study has provided us with excellent examples of thrust, strike-slip, and normal faults in the area. These classical examples offer a clearer picture of the tectonic history of the study area, which has wider application in understanding tectonic histories of many basins worldwide.

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“…While the external morphology of salt bodies is relatively well understood and can be imaged using 3D reflection seismic data, internal structures in 3D have only recently begun to be studied, using internal reflectors with high acoustic impedance contrasts (anhydrite + carbonate stringers) (Van Gent et al, 2011;Cartwright et al, 2012;Fiduk & Rowan, 2012;Jackson et al, 2014Jackson et al, , 2015Strozyk et al, 2014). A recent study (Raith et al, 2016) using high-resolution 3D seismic data, described the large-scale structure of the K-Mg salt-rich Zechstein 3, inside the Veendam salt pillow in the north European Zechstein basin. Nevertheless, the spatial resolution of 3D reflection seismic is limited and structures smaller than 25-30 m cannot be imaged.…”

Section: Introductionmentioning

confidence: 99%

Structural and microstructural analysis of K–Mg salt layers in the Zechstein 3 of the Veendam Pillow, NE Netherlands: development of a tectonic mélange during salt flow

Raith

Urai

Visser³

2017

Netherlands Journal of Geosciences

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In fully developed evaporite cycles, effective viscosity contrasts of up to five orders of magnitude are possible between different layers, but the structures and mechanics in evaporites with such extreme mechanical stratification are not well understood. The Zechstein 3 unit in the Veendam salt pillow in the Netherlands contains anhydrite, halite, carnallite and bischofite, showing this extreme mechanical stratification. The Veendam Pillow has a complex multiphase salt tectonic history as shown by seismic reflection data: salt withdrawal followed by convergent flow into the salt pillow produced ruptures and folds in the underlying Z3-anhydrite–carbonate stringer and deformed the soft Z3-1b layerWe analysed a unique carnallite- and bischofite-rich drill core from the soft Z3-1b layer by macroscale photography, bulk chemical methods, X-ray diffraction and optical microscopy. Results show high strain in the weaker bischofite- and carnallite-rich layers, with associated dynamic recrystallisation at very low differential stress, completely overprinting the original texture. Stronger layers formed by alternating beds of halite and carnallite show complex recumbent folding on different scales commonly interrupted by sub-horizontal shear zones with brittle deformation, veins and boudinage. We attribute this tectonic fragmentation to be associated with a softening of the complete Z3-1b subunit during its deformation. The result is a tectonic mélange with cm- to 10 m-size blocks with frequent folds and boudinage. We infer that these structures and processes are common in deformed, rheologically strongly stratified evaporites.

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Evolution of rheologically heterogeneous salt structures: a case study from the NE Netherlands

Cited by 22 publications

References 44 publications

Deformation of intrasalt competent layers in different modes of salt tectonics

Deformation of intrasalt competent layers in different modes of salt tectonics

Multiphase Structural Evolution and Geodynamic Implications of Messinian Salt‐Related Structures, Levant Basin, Offshore Israel

Structural and microstructural analysis of K–Mg salt layers in the Zechstein 3 of the Veendam Pillow, NE Netherlands: development of a tectonic mélange during salt flow

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